Mechanisms of Photochemical Reactions in Solution. XXV. The

PASADENA, CALIF.] Mechanisms of Photochemical Reactions in Solution. XXV. The Photodimerization of Coumarin'. BY GEORGE s. HAMMOND, CHARLES A...
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Aug. 5, 1964

PHOTODIMERIZATION OF COUMARIN

[CONTRIBUTION KO,3085 FROM

THE

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GATESASD CRELLIN LABORATORIES OF CHEMISTRY, CALIFORSIA INSTITUTE OF TECHNOLOGY, PASADENA, C A L I F . ]

Mechanisms of Photochemical Reactions in Solution. XXV. The Photodimerization of Coumarin' BY GEORGEs. HAMMOND, CHARLES A.

STOUT,' A N D -ANGEL0

A. L A M O L A ~

RECEIVED MARCH 3, 1964 Some details of t h e mechanism of the direct and sensitized photodimerization of coumarin have been worked out. I n nonpolar solvents such a s benzene, interaction of excited singlet coumarin with ground state coumarin leads only t o self-quenching. In polar solvents such as ethyl alcohol, interaction of excited singlet coumarin with ground state coumarin leads t o self-quenching and to t h e formation of the cis-head-to-head dimer ( I ) in very low yield. In t h e presence of triplet sensitizers such as benzophenone, t h e tvens-head-tohead dimer (11)is formed exclusively in both polar and nonpolar solvents. The formation of the trens-head-tohead dimer, which proceeds 'with a relatively high quantum yield, arises from interaction of excited triplet coumarin and ground state coumarin. In the sensitized reactions, triplet coumarin is produced by energy transfer from t h e excited triplet sensitizer. In the direct reaction a t high dilution, intersystem crossing in coumarin can compete with self-quenching and the trans-head-to-head dimer is produced without involving a sensitizer. Benzophenone controls the reaction in ethyl alcohol (trans-head-to-head dimer is formed ) even when most of t h e light is absorbed by coumarin. In this case, singlet excitation is transferred from coumarin t o benzophenone where intersystem crossing takes place. The triplet excitation is then transferred back t o coumarin.

Anet4 has reported t h a t irradiation of coumarin in ethanol solution produces a dimer, I, having the cis head-to-head structure. In contrast, Schenck, von Wilucki, and Krauchj found that irradiation of benzene solutions containing coumarin and benzophenone led to formation of the trans isomer TI, along with a trace of the trans-head-to-tail dimer 111. Irradiation of ethanol solutions containing both coumarin and benzophenone also produced 11. Irradiation of benzene solutions containing coumarin but no benzophenone produced no product a t all.

I

hv

S --+ .S. (excited, biradical state)

.s.+ x --+ .S-X. +-x'+ x --+ e-x-X' .S-X-X. --+ s + xx S

=

sensitizer; X = substrate

were much interested in the reports. Clearly the results do not unequivocally rule out the possible involvement of energy transfer in the benzophenonecontrolled reactions. For example, one could maintain that I is formed by attack of an excited singlet state of coumarin on ground state coumarin and that I1 and I11 are formed b y addition of coumarin triplets to coumarin. In addition, i t seemed possible that in one system or the other the isolated product might be formed by photoisomerization of a primary product. Various experiments were carried out to test these hypotheses and have led us to the conclusion t h a t the benzophenone-controlled reaction involves a remarkably complex mechanism involving two intermolecular energy transfers. Results and Discussioa

I1

111 h o t isolated from ethanol)

Schenck has pointed out t h a t the difference in the results obtained in the presence and in the absence of benzophenone indicate unequivocally t h a t different intermediates must be precursors of I and 11. He also concluded t h a t the results were also inconsistent with the view t h a t coumarin is activated by energy transfer from an excited state of benzophenone. The results would be easily understandable if the reactions in the presence of benzophenone are formulated according to the general mechanism suggested by Schenck to account for reactions effected by photosensitizers. Since we have maintained the view that energy transfer is a key step in many photosensitized reactions, we (1) P a r t X X I I ' is 1) 0.C o w a n , M M C o u c h , K . R K o p e c k y , a n d G. S. H a m m o n d , J . O u g C h r i n , 29, 1922 (19G4). ( 2 ) h'ational I n s t i t u t e s of H e a l t h P o s t d o c t o r a l Fellow. 1962-1963. (3) K a t i o n a l Science F o u n d a t i o n P r e d o c t o r a l Fellow, 1961--1964. (4) F. A L. A n e t , C a n . J . C h e m . , 40, 1249 (1962). ( 5 ) G 0. S c h e n c k , I. von Wilucki. a n d C. H. K r a u c h , Be?., 9 5 , 1409 (1962).

The possibility of photoisomerization of a primary product was first investigated. Suspensions of I in benzene were irradiated, both with and without benzophenone, for 37 hr. with the unfiltered light of a medium-pressure mercury arc. Similarly, I1 was irradiated in ethanol solution. In no case was any change observed. Examination of the details of the earlier experim e n t ~indicated ~ that the effect of benzophenone was not entirely straightforward since the ketone appeared to exert complete control over the course of the reaction despite the fact that most of the light must have been adsorbed by coumarin. In order to define the primary excitation process, irradiations were carried out so that virtually all of the incident light was absorbed by one or the other of the solutes. In all experiments the only product isolated was 11. Because of the very low solubility of I , i t is certain that no significant amount of that compound was formed. This w a s true even in a n experiment in which 99.1~57~ of the incident light was absorbed by coumarin. Since the absorption spectra of the solutions were additive, absorption by benzo-

I

I

I

I

I

I

1 30

.-ch'

69

waveiength,A.

Fig. 1.---Spectra i l l solutioii a t room temperature of (1) benzopheuone absorption (ill methyl alcohol), ( 2 ) coumarin absorptiori (in methyl alcohol), and (3) coumarin fluoresceiice (in ethyl alcohol ) .

phenone-coumarin complexes cannot have been significant. Apparently benzophenone is not a photosensitizer in the usual sense since it controls the course of the reaction even when it does not absorb the exciting light. The result is consistent with the view that energy acquired by coumarin by absorption is transferred to benzophenone as singlet excitation, and, after intersystem crossing, returned to coumarin as triplet excitation. The irans dimers IT and I11 would then be produced by addition of coumarin triplets to the parent compound hv

c +C*(l)

(1)

B*(Il +B*,3)

(3)

B*C3'

+ C +B + C*(3'

(4)

C"3'

+ c +I1 + I11

(5)

+ B +C + B*(']

C*(*)

(2)

Coumarin

Benzophenone

Fig. '.---The low-lying excited states of couriiarin and benzophenone. T h e fate of excitation absorbed originally by cournariti is traced by the arrows.

phenone which make the double energy transfer possible are shown schematically in Fig. 2. An entirely analogous situation, in which excitation was shuttled between two parts of the same molecule, was reported recently. Although the spectroscopic evidence seems rather conclusive, some curious features of the photochemistry remain to be accounted for. They are: (1) the fact that I is formed by direct irradiation of coumarin in ethanol, and (2) the fact t h a t no dimer is formed by irradiation of concentrated solutions of coumarin in benzene in the absence of benzophenone. In order to maintain a consistent picture i t is necessary to postulate that coumarin singlets are the precursors of I

Robust support of the above mechanism was obtained by emission spectroscopy. Solutions of coumarin show structureless fluorescence when irradiated a t room temperature. The fluorescence from a dilute absolute ethanol solution has maximum intensity a t 3575 A.6 and that from a benzene solution has a maximum a t 3640 .&. However, addition of benzophenone quenched the coumarin fluorescence in benzene solution. The quenching reaction is explained by energy transfer by a process such as reaction 2. T h a t transfer might be expected on the basis of the spectra of the two compounds is demonstrated by Fig. 1. There is extensive overlap between the emission spectrum of coumarin and the absorption spectrum of benzophenone. The emission spectrum of coumarin in ethanol-ethyl ether a t 7 i " K . shows both a short-lived component (fluorescence) and a long-lived component (pho;phorescence). The latter has an 0-0 band a t 4590 A. (62.2 kcal. per mole). Since the excitation energy of henzophenone triplets is 68.9kcal. per mole, we would rxpect them to transfer their excitation to coumarin a t a diffusion-controlled rate. The relationships among the low-lying excited states of coumarin and benzo-

The occurrence of reaction G is very reasonable a t the concentrations used (-0.3 .If). At such high concentrations there is a finite probability that some pairs of coumarin molecules will be nearest neighbors in solutiong and the probability that excited singlets will encounter ground-state molecules during their lifetime (7 G lop7 sec.) is very high. The real problem is to account for the nonoccurrence of reaction G in benzene. The dilemma is compounded by the thought t h a t if I is not produced, I1 probably should be. High conversions of coumarin to I1 can be effected in the presence of benzophenone in a process to which a triplet mechanism is assigned. Since the fluorescence and phosphorescence spectra of coumarin are of about equal intensity in a glass a t i i " K . , we must infer that the excited singlets undergo intersystem crossing with significant efficiency. Since I1 and I11 are not formed by direct irradiation in solution a t room temperature. some process other than reaction G must compete with

( 6 ) T h e m a x i m u m of fluorescence i n t e n s i t y f o r a d i l u t e solution of cou;% e t h a n o l \ \ a s r e p o r t e d as :X13 .i 7 U'heelock. J A m C h r m S o r . , 81, 1,'148 (1959).

IS) P A T.eermakeri, C:. \V. E y e r s , A A 1,arnola. a n d 0 . S H a r n m o n d . $ b i d , 85, 2670 (196:H i l l ) G S H a m m o n d a n d H P LYaits, ibid , 8 8 , 1911 ( 1 U 6 4 l

C*"'

ks + c ---+ I

(6)

PHOTODIMERIZATION OF COUMARIK

Xug. 5 , 1964

intersys tem crossing. il:e believe this competitive process must be self-quenching, reaction 7 C*(”

k; +C+ 2C + energy

(7)

Since the yield of I is low in ethanol, i t is necessary to assume that reaction 7 is the principal mode of destruction of C*(” in both ethanol and benzene. I n ethanol the rate kg’ki is small b u t measurable; in benzene the ratio is too small to be detectable. This merely indicates that the relative rates of the bimolecular reactions of C*il’ are subject to solvent effects. Since the excited singlet is a polar molecule, one might expect such solvent effects. Intuitively, we expect t h a t the principal .effect will. show up in reaction 6 , the chemical process, b u t there is no way of making such an allocation on a rigorous basis a t this time. T h a t the rate of dimerization relative to self quenching is faster in polar than in nonpolar solvents was demonstrated by direct irradiation in other solvents. In dimethyl sulfoxide, dimethylformamide, and glacial acetic acid compound I was produced. In fact, the conversion rate in acetic acid is considerably faster than in ethanol. Irradiation in dioxane, a less polar solvent, gave no dimer. However, in mixtures of benzene and ethanol or dioxane and ethanol, compound I was formed b u t a t a lower rate than in pure ethanol. Clearly benzene and dioxane do not exert special inhibitory influences. If the reasoning concerning the fate of C*(” is correct, intersystem crossing of excited coumarin singlets should be observed in dilute solutions.

-

c*ri’

~ “ 3 )

(8)

Irradiation of a 0.01 M solution of coumarin in benzene resulted in production of 11. The rate of formation was lower than in experiments with benzophenone, indicating that nonradiative decay of coumarin triplets competes with addition, reaction 5 . T h e expertment demonstrates that benzophenone i s not a necessary agent an the f o r m a t i o n o j 11 a n d proves rigorously that the Schenck mechanism is not an exclusive path f o r f o r m a t i o n of 11. The result also carries the strong implication t h a t energy transfer, rather than addition and elimination, is responsible for the reaction in the presence of benzophenone. Experimental Materials.-Coumarin drarvn from stock did not bear a supplier’s label b u t was found to have a sharp melting point in agreement with values recorded in the literature. Benzophenone from Matheson Coleman and Bell was used without additional purification. Absolute ethanol and benzene (Baker and Adamson, ACS Reagent Grade) were used without further purification. Dioxane was distilled from the sodium ketyl of benzophenone and stored in the frozen state under nitrogen. Glacial acetic acid ( d u Pont Reagent Grade) was used as supplied. Dimethyl sulfoxide was stored over a molecular sieve. Dimethylformamide was purified by passage through a column of activated alumina. Fluorenone was Eastman Kodak Reagent Grade. Acetophenone was Matheson Coleman and Bell Reagent Grade. Ethyl coumarate was prepared by the method of Fries and Klostermann.l0 ilfter six recrystallizations from benzene-petroleum ether (with one treatment with activated charcoal) the product was pale yellow, m.p. 8i.5-88.5”. The yield of purified product was L5.2 g. 139.55,). Spectra.-Ultraviolct absorption spectra were measured with a Car?. Model 14 recording spectrometer. Emission spectra were measured with a photoelectric spectrophosphorirneter consisting (10) K . Fries and W. K l o s t e r m a n n , A n n . , 363, 1 (1908)

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of a Jarrell Ash Ebert scanning monochromator (f/S), and ELI1 9558 photomultiplier tube and appropriate recording electronics. Phosphorescence is separated from fluorescence by means of a “rotating can” phosphoroscope which is removed when total emission is measured. Excitation is supplied by a General Electric A1H4mercury lamp with filJers suitable for isolation of the group 01 lines a t 3130 and 3660 A . The fluorescence from a degassed solution of coumarin i n absolute ethyl @coho1 (10 mg. in 3 c c . ) a t room temperature begins a t 3400 A . with maximum intensity a t 3575 A . In benzene a t the same concentradion and temperature, the coumarjn fluorescence begins a t 3500 A . with niaximum intensity a t 3610 A . Addition of 20 mg. of benzophenone to the benzene solution completely quenched the coumarin fluorescence. The phosphorescence and fluorescence emission recorded at --0 i i I(.were for a 0.1 AT solution of coumarin in a mixture of one part diethyl ether and two parts ethyl alcohol by volume. Irradiation Procedures .--Irradiations were carried out using an emersion apparatus supplied by the Hanovia Lamp Division of Englehard Industries. The lamp usually used was a 450-watt, medium-pressure, mercury arc, Type Number 679.1. A 200watt lamp was used in some preliminary experiments. Tubes were suspended on the outside of the cylindrical reaction well and the entire assembly was immersed in a large beaker of water. S o attempt was made to maintain constant temperature, but the water temperature did not rise above about 35”. Cylindrical glass filters, when used, were placed inside the lamp well. Filter solutions were placed in the well jacket providing a 1.8-cm. liquid-filter layer. Unless otherwise specified, the ampoules were prepared from Pyrex test tubes having a 25-mm. diameter. After loading, the tubes were flushed with a stream of nitrogen and sealed. Absence of Complexes.-Solutions containing 0.1 AT benzophenone and coumarin were mixed and their absorbanc$s were measured in the spectral region between 3850 and -1100 -4. S o departure from additivity was observed in either methanol or benzene. Direct Irradiation in Ethanol.--A solution of 12.3 g. of coumarin was divided among three tubes. The tubes were degassed, sealed in oucuo, and irradiated without a filter with the 200-watt lamp for 72 hr. The tubes were opened and the crystalline product was removed by filtration and recrystallized from glacial acetic acid. The yield of I, m . p . 272-274”, was 1 g. 18cCj. The results essentially duplicate those of .111et.~ Effects of Benzophenone.-A solution containing 3.65 g . (0.5 M )coumarin and 14.3 g. (1.57 -$f) benzophenone in 50 r n l . of benzene was divided between two Pyrex tubes and irradiated for (0.5 hr. filtering the light with uranium glass which is opaque t o light of wave lengths shorterothan 3340 8. 1.irtually all the absorbed light was in the 3660 A . mercury line. Since the ratio B B / C C is 94 a t 3650, 98‘’; of the exciting light was adsorbed by the benzophenone. The contents of the two tubes were combined and the solvent was removed by evaporation. The residual oil slowly became a crystalline crust after cooling. The crystals were washed with benzene and vacuum dried. The residue was 1.234 g. ( 3 3 . 8 5 ) of crude 11, m.p. 163-165’. A solution containing i . 3 g . of coumarin (0.5 M) and 0.91 g . (0.05 M ) of benzophenone was divided among three Pyrex tubes and irradiated through a filter solution prepared by dissolution of 46 g . of S i S O a ’ H n Oand 14 g. of C o S O I . i H , O in 100 ml. of water. One-cm. layers of the solution have optical densities of 2.15, 0.23, 0.025, and 0.001 a t 3660, 3341, 3130, and 3025 A . , respectively. Using these d a t a , the spectral distribution for Hanovia Lamp No. 679A as described by the supplier, and the extinction coefficients of coumarin and benzophenone a t the four wave lengths, we estimate t h a t 99.157; o the exciting light was absorbed by coumarin. The irradiation was carried out for 80 hr. and the product was isolated in the usual manner by recrystallization from benzene. The yield of I1 was 0.571 g. ( 7 . 8 ( 7 ) . In three parallel experiments 3.48-g. samples of coumarin were dissolved in 25 ml. of dioxane along with sui-fcient benzophenone to make the solutions 0.11, 0.011, and 0.0013 J I with respect to the latter solute. The tubes were irradiated with the unfiltered light from the 450-watt lamp. The first two tubes were irradiated 82 hr., the third for 79.5 hr. The products were isolated as usual and recrystallized several times from benzene; the yields from tubes 1 and 2 were 2.77 (79.5‘;) and 2.68 g. ( 7 6 . 7 ( < )of 11. The product from the third tube was recrystallized from ethyl acetate-toluene mixture giving a new material, m . p . 159.8161.9” On melting, the material evolved a gas, resolidified,

--

A. K . COLTER,S. S.WANG,G. H. MEGERLE, ASD P. S OSSIP

;I106

and remelted a t 178.8-179.3', the melting point of 11. The infrared spectrum of the material had bands, inter alia, a t 3410, 1755, and 1710 cm.-'. The product is believed t o be a mixture of I V and V , and is probably formed by reaction with water and ethanol during isolation.

O

IV

0

v

The combined &-eight of all fractions was 0.506 g. (-15%). Since a different material was isolated, the yield cannot be compared with those in the parallel experiments, b u t the result does show that dimerization occurs even with a coumarin : benzophenone ratio of 720. Effect of Acetophenone.-A solution of 3.48 g. of coumarin and 0.06 g. of acetophenone in 25 ml. of benzene was irradiated in a Pyrex tube for 79.5 hr. The product was recrystallized from ethyl acetate-toluene giving 392 mg. ( l l c c )of a material that melted a t 159.6-161.9" with evolution of a vapor, resolidified, and remelted a t 178.8-179.3', the melting point of 11. The product initially isolated is believed to be 1'1 and/or V formed by ring opening by adventitious water or alcohol d ring isolation (t'ide s u p r a ) . Effect of Fluorenone.-.% solution of 3.48 g. of coumarin and 0.06 g . of fliiorenone in 25 nil. of benzene was irradiated in a Pyrex tube for 79.5 hr. with unfiltered light. Two products were isolated, 441 mg. (12.7r;) of I1 and 856 mg. ( 2 4 5 ) of the ringopened prodiirt (vide s u p r a ) derived from 11. Direct Irradiation in Benzene at High Dilution.-Twenty 12 X 100 tnrn. Kitnex tubes were loaded with 3 tnl. each of 0.01 M solutions of coumarin in benzene. The solutions were degassed with three freeze-thaw cycles, sealed in uucuo, and irradiated for 71 hr. with unfiltered light from t h 450-watt lamp. The contents of the tubes were combined and solvent was removed by evaporation under a stream of air. The residual scum was taken up in hot toluene and after four recrystallizations yielded 10 mg. ( l l r ; ) of 11, tn.p. 179.8-180.6'. The infrared spectrum was identical with t h a t of pure 11.

[ C O N T R I B U T I O S FROM T H E

DEPARTMENT O F CHEMISTRY,

1701.

so

Direct Irradiation in Benzene-Ethanol,-.i lii-g. sample of coumarin was dissolved in a mixture of 100 nil. of benzene and 25 m . of ethanol and divided among four Pyres tubes. 'l'lle S I I ~ U tions were flushed with nitrogen, sealed, and irradiated nith U I I filtered light for 94 hr. The product was isolated a n d recrystallized from glacial acetic acid, giving 320 ing. ( 2 ) of I . Direct Irradiation in Dioxane-Ethanol,-.$ solution of 3 g. of couniar'n in 2 nil. o ethanol aiid 2 inl. of dioxane was placed in a Pyrex tube, flushed with nitrogen, sealed, and irradiated for 82 hr. with unfiltered light. The yellow solution was wnrketl up as usual, yielding 24 m g . (0.8('; of I after one recrystallizatio~~. Irradiation in Dimethyl Sulfoxide.--A solution of 3.48 g . of coumarin in .XI nil. of DMSO was irradiated i n five nitrogenflushed, Pyres tubes with unfiltered light for 76.5 hr. 'The yellow solution was concentrated a t 1 m m . , leaving a viscous yellow residue. Benzene was added and crystals slowly forincd. The infrared spectrum of the product was identical with that of an authentic sample of I ; yield 130.8 rng. ( : 3 . 7 ( ' ;j . rradiation in Dimethy1formamide.-The experiment was a duplicate of the previous one except t h a t the solvent w a s 30 nil. of D M F . The yield of I was 70.3 trig. ( 2 ( 0 . Irradiation in Acetic Acid.-The esperimeilt was a duplicate of the previous two except that 3.0 g. of coumarin was dissolved in 30 1111. of glacial acetic acid and irradiation was terminated after 18 hr. The yield of I was 0 . f M g . (21,4(';1. Irradiation of Ethyl Coumarate.--A solution of 1.01 g. of ethyl coumarate in 31) nil. of benzene was degassed, sealed in w t z l o , and irradiated i n a Pyrex tube with unfiltere , light for 72.5 hr. Only coumarin was isolated from the mixture. An ideiitical experiment was carried out with 0.99 g. of benzophenone added t o the mixture. .A crystalline product which separated during irradiation was recrystallized three times from benzene and sublimed in W K I L O to give 50 mg., white crystals, m.p. 198". The product was not further investigated. X solution containing 1.003 g . of ethyl coumarate and 0.102 g . of coumarin in 30 nil. of benzene was degassed and irradiated with unfiltered light for 72.5 hr. Only coumarin could be isolated f rom the m i k ture .

Acknowledgment.-This study was partially supported by a grant from the Sational Science Foundation, (11) N O ~ AED D E D I U PROOF.-Recent mecsiilements suggest strongly t h a t t r a n s f e r of singlet energy f r o m coumarin t o benzophenone involve:: emission and reabsorption of light.

C A R S E G I E INSTITUTE O F

TECHNOLOGY, PITTSBURGH 13, P E S S A ]

Chemical Behavior of Charge-Transfer Complexes. 11. Phenanthrene Catalysis in Acetolysis of 2,4,7-Trinitro-9-fluorenyl @-Toluenesulfonate1s2 BY ALLAS K . COLTER, SAMCEL S. L l r . 4 ~GEORGE ~, H . ~ I E G E RASD L E ,PAULS. OSSIP RECEIVED M A R C H 16, 1961 Acetolysis of 2,4,7-trinitro-9-fluorenyl p-toluenasulfonate ( 1 ) is accelerated by added phenanthrene. Rates of acetolysis were measured a t a series of phenanthrene concentrations a t 55.85, 70.0, 85.0, and 99.9'. Rates increase with increasing phenanthrene concentration up to 5.16 times the uncatalyzed rate a t 0.086 .If phenanthrene ( 7 0 . 0 " ) , the highest concentration studied. ;Ipparent (formal) activation parameters (700 " ) vary from AH* = 25.7 kcal. mole-', AS* = -11.7 e u . mole-', in the absence of phenanthrene, t o AH* = 22.4 kcal mole-', AS* = - 18.3 e.u. mole-1 a t 0.08 .\I phenanthrene. The data were analyzed in tarnis of a mechanism involving 1 : 1 complesing between phenanthrene and substrate. The analysis leads to values of K T , the equilibrium constant for 1 : 1 complex formation, and k,. the specific rate of acetolysis of the 1: 1 complex, a t 55.85, 70 0,and 85 0'. The 1 : 1 complex is 21 tCJ 27 times a s reactive in acetolysis as uncomplexed substrate a t these temperatures. Values of KT are in good agreement with values estimated by a n independent spectrophoto26 kcal. metric study. Activation parameters for acetolysis of the 1 : 1 complex were estimated to be AH* - 5 e . u . mole-', showing t h a t the 1 : 1 complex is more reactive in acetolysis than the unconimole-' and A S * plexed substrate because of a more favorable entropy of activation. T h e significance of these results is discussed.

Introduction The field of organic molecular complexes of the donoracceptor type has been a very active one during the past ( 1 ) A preliminary r e p o r t of a portion of t h i s work h a s a p p e a r e d : A . K . Colter a n d S . S W a n g , J . A m C h r m . S o ' , b6, 11.5 (1963) ( p a r t I of t h i s serie-1

d e ~ a d e . However, ~ relatively little attention appears to have been given to the possible effects of C o I n p l C X ( 2 ) Abstracted in p a r t f r o m a thesis s u b m i t t e d b y s S . W a n a i n pat-tial fulfillment of t h e requirements for t h e degree of Doctor of Philosophy a t t l l c Cat-negie I n s t i t u t e of Technoloyy J u n e , 1!161 ( X ! G . Briegleb, "Electronen-Donator-Acceptor-Knmplexe," S p i i n w i Vel-lay, Berlin, l Y G l .